Conveyer



a J. O'LIE'ARY Sept. 7, 1954 oNvEYER a Sheets-Sheet 1 Filed Jan. 6. 1950 mveumn C. J. O'LEARY k w u.

ATTORNEY v c. J. O'LEARY Sept. 7, 1954 CONVEYER Filed Jan. 6, 1950 8 Sheets-Sheet? V INVENTDR c. J. O'LEARY ATTORNEY C. J. -O'LEARY Se t. 7, 1954 com 8 SheetsPSheet 3 Filed J m, 6, 1950 INVE N TOR 75 61.1 ozum ATTORNEY Sept 7, 1954 c. J. OLEARY coNvEYER Filed Jan. 6, 1950 gsheets-sneet 4 J OLgA/y ATfOR/VEY C. J. O'LEARY Sept. 7, 1954 CONVEYER 8 Sheets-Sheet 5 Filed Jan. 6. 1950 ATTORNEY Sept. 7, 1954 c. J. OLEARY/ CONVEYER Filed Jan. 6. 1950 8 Sheets$heet '7 Sept. 7, 1954 c. J. O'LEARY CONVEYER f 8 Sheets-Sheet 8 Filed Jan. 6, 1950 wvavron C. J OZEARV' ATTORNEY I Patented Sept. 7, 1954 {UNITED s TATES .ATNT OFFICE CONVEYER Charles J. 0,-Leary, Baltimore, Md., .assignor to Western Electric Company, Incorporated, New York, L, .a corporation of New York Application January 6, 1950, Seria-INo. 137,226

- improved conveyors.

another object of the invention is to provide :new and'improved conveyor apparatus which *delivers articles to .a plurality of stations in a se- --:quence determined at a point where :the articles are :placed on the apparatus.

In one apparatus illustrating certain features of the invention .as applied to :a conveyor for selectively transporting tubs containing .a hatch of ingredients to a :series of mixing machines,

there :is provided; a .plurality of manually-operable contacting elements at the beginning of thelconveyor, one for each mixing machine 'Whenthe cont-acting elements are actuated, they initiate the-operation of automatic-circuit connections to .cause the {tubs to be delivered to the mixing machines in the sequence in which the contacting elements are :operated. The circuit connections the .conveyor to deliver the tubs to the mixing machines in accordance with the sequence in which :the contacting elements were operated. The circuits associated with the contacting ele- =,ments are provided with means for =cancel1ing a preselected destination for ;a particular tub so that :it may be rerouted to any of the other destinations by subsequent operation of its respective contacting element.

.Aclear understanding of the invention may he had .by reierring to the {following detailed description .of .a specific embodiment thereof, when read in conjunction with the appended drawings, in which:

Fig. 1 is a schematic diagram of a conveyor a paratus embodying the present invention;

Fig. 2 is an enlarged .view of a master control panel forming a part of the conveyor apparatus shown in Fig. 1,;

Fig. 3 is a perspective view of a coordinate switch system;

Fig. 4 is an enlarged, Iragmqentary perspective view of .a portion .of the coordinate switchsystem shown ,in ,Fig. 3;

Fig. 5 is a sectional view taken alon line 5--,5 of Fig. 4;

.a manner well .known to the mixing .art.

Figs. 6 to 11, inclusive, are schematic circuit diagrams showing portions of the various :control circuits for the conveyor apparatus shown in Fig. 1, and are arrangedso that when Fig. 7 is placed to the right of Big. 6, Fig. 8 is placed beneath Fig. 6, Fig 9 is placed to the right of Fig. -8 and beneath Fig. '7, Fig. 10 is placed beneath :Fig. '8, and Fig. 11 is placed to the right of Fig. 10 and beneath Fig. .9, these figures show schematically the entire electrical circuit rfor controlling the conveyor shown in Fig. 1.

Referring to thedrawings, wherein like reference characters designate identical partsxthroughout the several views, and more particularly to .Fig. 1, there is shown a schematic -arrangement .Of .a conveyor .for selectively conveying materials in tubs from .a floor 2G to .a plurality of mixing machines 21, .22, .23 and a l positionedon a hoot indicated by the numeral .26. The mixing Ina- .chines 2.! to .26, inclusive, may be of various types depending upon .the materials to be mi-xed therein. However, forthepurpose of illustrating the present invention, let it be assumed that the .mixing machines are Banbury mixers which .operate in The mixing machines .21 to '24, inclusive, are arranged to mixsuccessive batches of ingredients generally used in compounding rubber and rubber-likeicompounds of thetype used for insulating and Jacketing electrical conductors. Each batch of material is mixed for a predetermined time, after which the mixing machine discharges the mixed batch into suitable apparatus which prepares the compound for use in conventional extruding machines well known in the art of manufacturing insulated electrical conductors.

The conveyor shown in Fig. 1 comprises a level conveyor section 28 located on the floor 28, on which'rectangular tubs et3ll may be positioned and rolled along manually from left to right as various components of a particular insulating compound are deposited into the tubs. When the tubs receive the proper ingredients lfOl' a particular batch of compound, they pass onto a gravity conveyor at which directs them to apower driven conveyor 32 positioned at the base of a shaft .34 in which a hoist 35 travels between the floor :20 and the floor 28. The hoist is controlled electrically in a conventional manner so that it is normally positioned at the door 26 and is provided with a circuit controlling switch actuated by the tubs which cause the hoist to be elevated to the floor .26 each time a tub is positioned on the hoist by the power conveyor 32. The floor of the hoist 3.5 is provided with conventional anti-friction means (not shown) to permit a tub 30 positioned thereupon to roll oil the hoist when it reaches the floor 26.

The tub 39 positioned on the hoist 35 rolls onto a gravity conveyor 36 which conveys the tub to a level, power driven conveyor 38 mounted on the floor 26. The power conveyor feeds the tubs to the mixing machines 2|, 22, 23 and 24 by means of spur conveyors 49, 4|, 44 and 45 which may be selectively connected to the conveyor 38 by switch sections 48, 49 and 59. The switch sections are operated by motors and associated control circuits so as to direct the tubs to the preselected mixing machine in accordance with a preselected sequence of delivery of the tubs which was determined at the time the empty tubs were positioned on the conveyor 28.

A gravity conveyor 53 carries the empty tubs from the mixing machines to a shaft 55 having a hoist 56 operable therein between the floor 26 and the floor 28. The hoist 56 normally is positioned at the floor 26, and is controlled by suitable electrical circuits so that when an empty tub from one of the mixing machines rolls onto the hoist 56, it actuates limit switches (not shown) positioned in the hoist, the operation of which causes the hoist 56 to be lowered to the floor 26. The hoist delivers the empty tubs to a gravity conveyor 51 mounted on the floor 29 so that the tubs collect at the starting point of the level conveyor 28. Each time an empty tub rolls off the hoist 56, the hoist returns to its position opposite the delivery end of the gravity conveyor 53.

The operation of the hoists 35 and 56 is controlled by conventional electrical circuits and limit switches which do not form any part of the present invention. The structural features of the conveyors are relatively unimportant herein and have not been shown in detail, since general conveyor practices are well understood in the art. It is believed to be sufficient at this point to state that the conveyor 28 is provided with a plurality of rollers, which permit the tubs 30-39 to be rolled therealong as they receive their ingredients for delivery to the mixers 2! to 24. inclusive, that the conveyors 3!, 36, 53 and 51 are arranged to continue the movement of the tubs in the proper direction by gravity. and that the power driven sections 32 and 38 of the conveyor serve to carry the tubs at a predetermined rate of speed determined by the operation of the mixing machines.

The conveyor apparatus shown in Fig. 1 is provided with a control panel 60 positioned near the left-hand end of the level conveyor 28, which is connected to the electrical circuits shown in Figs. 6 to 11, inclusive, so that the switch sections 48, 49 and 50 will operate in a sequence determined when each of the tubs enters the conveyor 28. An enlarged view of the control panel 69 is shown in Fig. 2, and as shown, it includes four vertical rows of indicating lamps Iii-6! wherein each row consists of three lamps. Each row of lamps is connected to conventional limit switches 62-62 positioned on the spur conveyors 40, 4|, 44 and 45 to indicate the number of filled tubs positioned at each of the mixing machines. From this arrangement of the switches 62-62, it can be determined readily which of the Banbury mixing machines has an adequate supply of material tubs 39-39 on hand. The spur conveyors 40, 4|, 44 and 46 are designed to have a length sufiicient to store a predetermined number of tubs. 30-30 thereon in order that an 4 adequate supply of material may be on hand for their respective mixing machine.

The control panel 66 also is provided with four push buttons 64 to 61, inclusive, which are connected in the circuits shown in Figs. 6 to 11, inclusive, so that they control the opertaion of the switch sections 48, 49 and 50. A bank of indicating lamps 10-10 are provided on the control panel 69 beneath the push buttons which are arranged in a manner hereinafter to be described to indicate the sequence of operation of the push buttons 64 to 61, inclusive. On the right hand side of the panel, there is provided a plurality of reset push buttons H to 16, inclusive, which permit the preselected destination of any tub to be cancelled so that the particular tub may be assigned to another destination provided the particular tub has not reached the hoist 35.

The batch material tubs 30-30 move along the level conveyor 28 at a rate faster than the hoist 35 can deliver them to the gravity conveyor 36 and the power conveyor 38, in which case, a plurality of tubs collect at the conveyors 3| and 32, with the foremost tub positioned on the power conveyor 32. It is believed to be apparent that while the hoist carries the first tub to the conveyor 36 the circuits controlling the operation of the switches 48, 49 and 50 must be stored in a suitable switch mechanism so that as each tub is delivered to the power conveyor 38 it will be directed to its destination as determined by the sequence operation of the push buttons 64 to 61, inclusive.

Any suitable switch mechanism, which will accomplish the desired results, may be used so long as it is capable of operating in the manner described. One type of switching apparatus which may be used, shown in Figs. 3, 4 and 5, is a coordinate switching mechanism used extensively in the telephone industry and known as a crossbar switch mechanism. A typical crossbar switch mechanism is disclosed in Patent 2,- 021,329 issued to J. N. Reynolds, November 19, 1935, and in a number of issues of vol. XVII (September 1938 through August 1939) of the Bell Laboratories Record, published by the Bell Telephone Laboratories, Inc. Consequently, the crossbar switch mechanism shown in Fig. 3 will be described herein only insofar as it is necessary for a complete understanding of the invention. Fig. 3 shows a typical crossbar switch mechanism indicated generally at 19, which consists of a rectangular frame having three double element electromagnets 80, BI and 82 mounted on the left-hand end of the frame, and two double element electromagnets 83 and 84 mounted on the right-hand end of the frame. Horizontal bars 86 to 90, inclusive, are suitably journalled in the ends of the frame so that each electromagnet is arranged to rotate one of the selecting bars a small amount in either direction depending on which element of the magnet is energized. Ten vertical columns of contact members 92-92 are resiliently mounted on vertical supports 93-93. The contact members of each column are arranged in ten groups of contacts, or two groups per bar, so that a group of contact members is positioned slightly above the selecting bar and another group of contact members is positioned slightly below the seletcing bar. Each group of contacts may contain as many normally open contacts as the circuit requires, like the normally open contacts 94-94 and 95-95 which are resiliently secured to the supports 93-93 by springs 96-96 (Fig. 4).

ithat particular position.

The selecting bars :86 to .90, inclusive, are provided with resilient selecting fingers -9 l-9:'I :(Figs. 3, 4 and 5) which extend inwardly from the selecting bars at points adjacent to each group of contacts of the vertical columns of the contact members 92-92. When the selecting bars are in their normal position, the resilient fingers are aligned with the opening between its respective group of contact members. When the bars are rotated in either direction (Fig. 14"), :-by their associated electromagnet, the resilient fingers assume their dotted line position as seen in 4, across the :backs of the upper group of contactsof each vertical column, and when they are rotated in the opposite direction the resilient lingers are positioned in back of the lower group of contacts of each :vertical column of contact members.

A holding bar 98 is :pivotally mounted between the top and bottom members of the frame ad- Jacent to each vertical column of contact mem- =bers9'2--9.2 The'holding liars-138 98 are actuated -by electromagnets 1.98 to .1'09, "inclusive, suitably mountedalong the base of the rectangular frame of the crossbar switch mechanism. When the electromagnets 80 to 84, inclusive, are energized, they rotate their associated selecting bar so as to move all the resilient fingers thereon directly behind the upper contacts 92l9'4 :or the lower contacts 95-415 of each group of contacts. When :cneof the holding magnets (Hill to 4119, inclusive, are subsequently energized, it turns the pivotal- .=ly :mounted :hol'din'g bar "so that it engages the rend of the resilient .fin'ger positioned adjacent to the vertical column associated with the energized coil :and closes the contact members 'at The holding .bar re- :mains operated until its associated magnet coil is deen'ergized, but the selecting :bar returns to its normal position immediately :after the holding bar :is operated. When the selecting bar returns to its central position, all the fingers return with it except the one aheld by the holding bar, thus, leaving the particular selecting loar free for operation with a different holding bar 9B of the coordinate .swlitch mechanism. "The resilient tfin'gers which remain ":in their normal position are moved between the :upper and "lower :groups of contacts, and therefore, do not actu- .:ate:any of the contacts of the vertical column of contact members HZ-92.

.In using .a crossbar switch mechanism like that described, 'to control the conveyor system shown :in Fig. 1, an electromagnet lor "operating :.theselecting bars must the provided *lor each mining machine, in which case, only two selecting bars and four electromagnets are needed i n the electrical circuits :shown-in Figs. *6 'Ito i jl, inclusive. 'Flhenum'ber of horizontal hol-d'in'g bars 19.8-98 and "their associated "electrom-agnets Hill .to .109, inclusive, is determined by the number w'of circuits which :must :be stored up in the :mechanism for the tubs Waiting [on the .conveyors 3| and 32 to .be picked up by the Lhoist Only six holding circuits are illustrated in .the electrical circuit diagram I'fDI the purpose of illustrating certain features of the invention.

.tReferring now to the schematic wining diagram shown in Figs. T6 to :l'l, inclusive, there is provided a pair of low voltage @husses Zlilll and 1| H which supply "a suitable D. C. potential to the electrical :apparatus required to control the operation of the switches A3; 49 and 5c of the conveyor L38. :Referring particularly to Fig. 96,

.operating coil M4 eof a relay l lfi is coontJi nected across the busses -I I0 and I H series with 'a normally open contact H6 provided on a relay ill, anormally closed contact I2 0 provided on a relay 12 a normally closed contact I15 provided on a relay [-25, a normally closed contact Il-B provided on a relay I28, and a normally closed contact of the push button =64. Each of the push buttons 64 to -61, inclusive, is provided with a normally closed. and .a normally open contact.

The relay H1 (Fig. 6-) has its operating coil Nil connected across the busses l [:0 and 111 in series with the normally open contact of the push butt-on 64. When the push button .64 is actuated to close its normally open contact, the coil 13!) is energized and closes its normally open contact H6. ,Enengization of the coil 13!] also closes its normally open contact 132 which connects 'a .coil 1-34 of a relay 53:5 directly :across the busses Ill] and ill. Energization of the coil I34 closes its normally open contact 1'35 which in turn-connects a magnet coil 13:! (Fig. 7) of the double element electromagnet .80 directly across the busses Hill and 11H. operating coil hill of a relay MI is connected across the busses H1) and Hal in series with a parallel circuit including a normally open contact I38 of the relay I35, a normally open contact I43 of a relay 1'44, a normally own contact 146 of a relay ll-l, and a normally open contact 1350 of a relay I5'l. An operating "coil 153 -(=Fig. 6) of a relay 154 is connected across the busses lzlil and. 1H in series with a parallel circuit including normally open contacts "I55, 155,. 1:61) and 1 62 provided on relays H5, 151, i261 and 183, respectively. An operating coil H35 of the relay El i-l is connected across the bosses Hill and I'll in series with a contact 1 66 provided on the relay H21, a normally open contact ill! 'of the relay 121, a normally closed contact l'i'fl provided on the relay 1-26, a normally closed contact HI provided on the relay 1'29 and the normally closed contact of the push butvton -65.

A coil H3 GFig. 6), of the relay PM, is connected directly across the busses H11 and H1 in series with the normally open contact of the push button 65. A coil 174 "of the relay M4 is connected across the busses in series with anormally open-contact I' l-5 or" the relay 1.2-1. Anoperating coil ill (Fig. '7'), of the double element magnet isconnected across the busses in series with a normally open contact I18 of the relay M4. An operating coil 'I'Bll (Fig. 6) of the relay P61 is connectedacross the 'busses in ,series with a normally closed contact 181 of .-a relay @MTI, a normally closed contact 182 of .therelay 12A, a normally open contact 183 of the relay Alli. .a normally closed contact 185 .of therelay I29 and the normally closed contact of the push button 66. An operating coil l8?! of .the relay .126 .is connected across thebusses 11M] and .-i l l in Series with the normally open contactof the push .button 6'6. .Energization of the coil [8.] closes ,a normally open contact [96 which energizes an operating coil I9! of the relay M1. IIlhe coil .19! closes a normally open contact 1194, which in turn, connects 'anoperating'coil 1930f the dou- .ble..element magnet -.8! across the rbusses H0 and .LM. Actuation-of the push button 16.6 ienergizes the operatingcoils l8 and lei of the ,relays 1128 and 11-41 respectively, which in turn, :connect the operating coil I9 3 of the .magnet :81 across :the husses. vOlosure ;-Df the :relay 551 energizes the :nelay 1124i. When the button fi'fi isms-leased, itsenrelay I54.

An operating coil I95 (Fig. 6) of the relay I63 is connected across the busses H and III in series with normally closed contacts I96, I91 and I98 of the relays II1, I2I and I26, respectively, normally open contact 200 of the relay I29, and the normally closed contact of the push button 61. An operating coil 202 of the relay I29 is connected across the busses in series with the normally open contact of the push button 61. An operating coil 203 of the relay I I is connected across the busses in series with a normally open contact 204 of the relay I29. The coil 206 (Fig. '1) of the double element magnet 8I is connected across the busses in series with a normally open contact 201 (Fig. 6) of the relay I5I. The relays I29 and I63 each have a time delay mechanism like that described for the relays I26 and I6I.

An operating coil 2I0 (Fig. '7) of a relay 2, is connected across the busses II 0 and III in series with normally closed contacts M2, 2 I3, 2M and 2I5 provided on the relays I35, I44, I41, I5I, the normally open limit switch 2I1 and a normally closed limit switch 2I8. The relay 2 II is provided with a normally open contact 2 I9 which is connected in parallel with the normally open limit switch 2I1, and a second normally open contact 22I which connects an alarm bell 220 across the busses when the 'coil 2I0 is energized.

Each of the relays H5, H1, I2I, I26, I29, 151, I6I and I63 (Fig. 6) is provided with a time delay mechanism which is arranged to hold their respective contacts in their actuated positions for a predetermined period of time after their respective operating'coils are deenergized by the release of their associated push buttons 64 to 61, inclusive. Thus, when the push putton 64 is actuated to energize the coil I30 of the relay II1, the normally open contacts H6 and I32 are closed and remain closed after the push button is released. Upon its release, it energizes the coil I I4 of the relay II5 before the contact I96 of the relay II1 opens, while the contact I32 01' the relay maintains the coil I34 across the busses. As a result, the magnet coil I31 of the double element magnet 80 is energized and operates its respective resilient fingers before the contacts II 6 and. I32 drop open. The relay H5 is held in its actuated position by its time delay mechanism after the relay II 1 drops open. This same arrangement takes place upon the actuation of each of the push buttons 64 to 61, inclusive, with respect to the relays II5, II1, IZI, I26, I29, I51, I6I and I63.

Referring now to Figs. 8 and 9, it should be noted that only six holding magnets, namely, I 00 to I 05, inclusive, are shown on the drawings in connection with the double element magnets 80 and 8I described in connection with Figs. 6 and '7. The left hand vertical row of contact members 9292 is shown in a horizontal position in Fig. 9 and the normally horizontal selecting magnets 80 and 8| and their respective selecting bars 86 and 81 are shown in a vertical position to simplify the wiring diagram. Each of the holding coils I00 to I06, inclusive, has associated therewith a normally open contact shown in Fig. 8 which closes each time the coil is energized, and six pairs of normally open contacts as shown in Fig. 9. Since the same arrangement of contacts prevails throughout the coordinate switch mechanism, only the normally open contact 226 adjacent to the coil I00, the normally open contacts 230 and 23I associated with the coil I31, the normally open contacts 232 and 233 associated with the coil I11, and the contacts 234 and 235 associated with the magnet coil I33 and the contacts 236 and 231 associated with the coil 206 are identified by numbers on the drawing for the purpose of illustrating the operation of the coordinate switch mechanism.

The magnet coil I00 (Fig. 8), which turns the extreme left-hand holding bar 98 (Fig. 3), is connected across the busses III) and III in series with the normally open contacts 240 and I of the relays I54 and MI, respectively, the reset push button H and a normally closed contact 242 provided on a relay 243. The normally open contact 226 bridges the normally open contacts 240 and 24! and thereby maintains the coil I00 across the busses II 0 and III after the relays I 4I and I 54 are deenergized upon the opening of the relays I I5 and II 1 when their time delay mechanisms complete their respective operating cycles. A relay 244 has its operating coil connected in parallel with the magnet coil I00 and the reset button 1 I, and has its normally open contact connected across the busses II 0 and II I in series with the operating coil of a relay 241 and a normally open contact 248 provided on the relay MI.

The magnet coil IOI is connected across the busses H0 and III in series with a normally open contact 245 on the relay I54, a normally open contact 246 of the relay 241, a normally closed push button 12 mounted on the panel 60, and the normally closed contact 242 of the relay 243. The normally open contact of the coil IOI is connected in parallel with the contacts 245 and 246 so that it maintains the coil across the busses after the contacts 245 and 246 drop open. A relay 250 has its operating coil connected in parallel with the coil IM and the push button 12, and its normally open contact connected across the busses in series with a normally open contact 249 of the relay 241 and an operating coil of a relay 25I. The relay 25I is provided with two normally open contacts like the contacts 246 and 249 of the relay 241. The magnet coil I02 (Fig. 8) is connected across the busses in series with normally open contacts provided on the relays I54 and 25I, a normally closed push button 13 and the normally closed contact 242 (Fig. 9) of the relay 243. A normally open contact associated with the coil I02 is connected in parallel with the contacts of the relays I54 and 25I. A relay 252 has its coil connected in parallel with the coil I02, and its normally open contact across the busses in series with a normally open contact on the relay 25I and the operating coil of a relay 253.

The remaining magnet coils I03, I04 and I05 (Fig. 8) are connected across the busses H0 and III in the manner described above in conjunction with contacts provided on relays 253, 258, 26I, respectively, their associated reset push buttons 14, 15 and 16, respectively, and the relays 254 and 260, respectively. However, the magnet coils I03, I04 and I05 are maintained across the busses H0 and II I after the relays I M and I54 are deenergized, through their respective normally open contacts and a normally closed contact 256 provided on a relay 251. The relays 244, 250, 252, 254 and 260 are provided with a timing mechanism to retard the closing of their contacts when their respective coils are energized. A second normally open contact associated with the magnet coil I05 connects an 9' operating coil 263- of the relay 243 directly across the busses in series with a normally open contact I provided on the relay 261.

relays 212 to 211', inclusive, control the operation of the switches 48', 49 and 56-. Each of the relays 265' to 216, inclusive, and 212 to 216, inclusive, is provided with two normally open contacts and a normally closed contact which are connected to obtain sequential operation of the relays upon successive operation of a limit switch 282 having a normally open and a normally closed contact and positioned so as to be actuated by the hoist 35. The first operation of the switch 282 closes its normally open contact and it connects the operating coil of the relay 265 across the bus H6 and an intermediate bus 266 in series with normally closed contacts on the relays 216, 269, 268, 261, 266 and 265 in the'order named or in the reverse order of their numeral designation.

:One of the normally open contacts on the relay 265 is connected in parallel with its own normally closed contact to maintain the coil connected across the busses H6 and 266 when the switch 282 returns to its normal position. The intermediate bus 286 is connected to the bus H I through a normally closed contact 28! provided on the relay 251. The relay 251 has its operating coil 283 connected'across the busses H6 and III in series with a normally open contact of the relay 216 and the normally open contact on the limit switch 282.

When the switch 282 returns to its normal position, its normally closed contact connects the operating coil of the relay 212 across the busses I I6 and 286 in series with normally closed contacts provided on the relays 216, 215, 214, 213, 212 and a second normally open contact provided on the relay 265. The relay 212 has one of its normally open contacts connected in parallel with these normally closed contacts to maintain the relay energized when the switch 282 is actuated again by the hoist. The next succeeding operation of the limit switch 262 by the hoist closes its normally open contact and connects the operating coil of the relay 266 across the busses H6 and 286 in series with the normally closed contacts provided on the relay 216, 269, 268, 261, 266 and a second normally open contact which is closed by the prior energization of the relay 212. Likewise, the subsequent closure of the normally closed contact of the switch 282 connects the operating coil of the relay 213 across the busses H6 and 286 in series with the normally closed contact on the relays 216, 215, 214 and 213 in the order named, and a second normally open contact of the relay 266. Each time the relays 265 to 216, inclusive, and 212 to 211, inclusive, are actuated by successive operation of the limit switch 282, they maintain themselves energized across the busses H6 and 286 and in so doing they set up a circuit for the energization of the next succeeding relay in its respective series. For example, the relay 265 sets up a circuitfor the relay 266 and the relay 266 sets up a circuit for the relay 261 and so on through the respective series of relays. Likewise, the relay 212 sets up a circuit for the relay 213, which in turn, sets up a circuit for the relay 2'14 and so on throughout the entire series of relays in its respective series.

The switch sections 48, 49 and 56 of the conveyor 36 (Fig. 2) are arranged to be actuated by motors controlled by relays 2'85, 266 and 281, respectively, as shown in Figs. 9 and 11. The relay 285 (Fig. 9) is provided with an operating coil 296, which has one end terminal thereof connected to the bus H6 and the other terminal thereof connected to an intermediate bus 29!. The intermediate bus 29! is connected to a second intermediate bus 294 in series with a normally open contact 232 of the first pair of contacts in the second vertical row of contacts, a normally open contact 282 provided on the relay 212 (Fig. 8) and a normally closed contact 293 provided. on the relay 266, or a normally open contact of the second pair of contacts in the second row of vertical contacts, a normally open contact 295 provided on the relay 213 and a normally closed contact 296 provided on the relay 261, or a normally open contact of the third pair of contacts in the second row of contacts, a normally open contact 261 provided on the relay 214 and a normally closed contact 266 provided on the relay 268, or a normally open contact of the fourth pair of contacts in the second row of contacts, a normally open contact 366 provided on the relay 216, and a normally closed contact 36l provided on the relay 269, or a normally open contact of the fifth pair of contacts in the second row of contacts, a normally open contact 364 provided on the relay 216, and a normally closed contact 365 provided on the relay 216, or a normally open contact of the sixth pair ofcontacts in the second row of contacts, a normally open contact 366 provided on the relay 211, and a normally closed contact 361 provided on the relay 251. Thus, the operating coil 296 of the relay 285 is connected across the bus H6 and the intermediate bus 264 when any one of the holding coils 166 to A65, inclusive, is energized in conjunction with the energization of the coil 1511 of the double element magnet 86.

The operating coil 366 (Fig. 9) of the relay 286 has one terminal thereof connected directly to the bus H6 and the other terminal thereof connected directly to an intermediate bus 3! which is common to one of the normally open contacts of each pair of contacts in the third vertical row of contacts. of which the first pair are numbered 234 and 235. Likewise, the operating coil 369 of the relay 281 has one terminal connected to the bus I I6 and the other terminal connected to an intermediate bus 3H which is common to one of the normally open contacts of each pair of contacts in the fourth vertical row of contacts of which the first pair are numbered 236 and 261. The intermediate busses 3l6 and 3!! are connected to the bus 294 in the same manner as that described for the bus 291. The intermediate bus 296, which is common to the busses 29!, 316 and 31!, is connected to the bus Ill through a normally open limit switch 312 which is positioned adjacent to the gravity conveyor 36 (Fig. 2) so that it is actuated by the tubs 36:36 as they travel from the hoist to the conveyor 38. The power conveyor 38 terminates at a conveyor 46 which feeds the tubs to the first Banbury mixer 2|, and; therefore, does not require any switch section for the mixing machine 2!. Therefore, one contact of each pair of normally open con.-

tacts of the first vertical row of contacts is open circuited. When the limit switch 3| 2 is closed by a material tub, it completes a circuit for the coils 290, 308 and 309, of the relays 285, 266 and 281 which includes a, contact in one of the three vertical rows of contacts of the coordinate switch mechanism.

The lamps in the lamp bank 10 (Figs. 2 and 9), provided on the control panel 60, are arranged to indicate the sequence of operation of the push buttons 64 to 61, inclusive, as the material tubs 30-30 are dispatched on the conveyor 28. The lamps are shown in Fig. 9 in the same manner as they are shown on the panel 60 (Fig. 2), that is, in four vertical rows of six lamps each, one row of lamps being provided for each of the push buttons 64 to 61, inclusive. The first lamp in each vertical row has one terminal thereof connected together and to the bus H in series with a normally closed contact 320 of the relay 265 and the other terminal thereof connected to one side of the adjacent normally open contact of the first pair of contacts of each vertical row of contacts of the coordinate switch mechanism. The other sides of these contacts are connected together and to the bus Ill. The second lamp of each vertical row of lamps is connected in a similar manner except that each lamp is in series with a normally closed contact 32| of the relay 266. The third fourth, fifth and sixth lamps in each row are connected in series with normally closed contacts 322 to 325, inclusive (Fig. '1), provided on the relays 261 to 210, respectively.

As pointed out hereinabove, the push buttons 1| to 16, inclusive, mounted on the control panel 60 are provided for the purpose of cancelling a preselected destination of a particular batch material tub in order that it may be redirected to another destination. However, the cancellation of the preselected destination must be made while the particular tub is resting on the gravity conveyor 3| or the power conveyor 32. This arrangement is illustrated in Figs. 8 and 9 which show that the push buttons 1| to 16, inclusive, are bridged by normally open contacts 328 to 333, inclusive, provided on relays 265 to 210, respectively. When the first tub placed on the conveyor 28 rolls on the hoist 35 and the hoist leaves the bottom of the shaft and allows the limit switch 282 to resume its normal position, the operation of the relays 265 closes the contact 328. Thereafter the operation of the reset push buton 1| will not open the circuit to the particular holding coil because the contact 328 bridges the normally closed contact of the reset push button. It should be noted that while the limit switch 282 is described as being operated by the hoist 35, it may be positioned at some other point on the conveyor system so as to be actuated by the tub itself, in which case, a greater period of time may be provided for cancelling the preselected destination of the batch material tubs 3030.

Fig. 11 is a schematic wiring diagram of the circuits controlling the operation of the motors provided for actuating the switches 48, 49 and 50. The electrical apparatus associated with the motor control receives its potential from the busses 335 and 336 .which may be connected to a suitable source of A. C. potential. The relay 285 (Fig. 8) is provided with a normally open contact 340 which connects an operating coil 34| of a relay 342 across the busses 335 and 336 in series with a normally closed contact 343 provided on a relay 344 and a normally closed limit switch 345 positioned to be actuated to its open normally closed limit switch 310. The relay 366 switch 350 is positioned adjacent to the gravity 1 conveyor 4| so that it is actuated to its closed position by a tub passing along the conveyor 4| and the limit switch 348 is positioned so as to be held in its open position by the switch 48 when it is aligned with the power conveyor 38. The

relay 344 is provided with a normally open contact connected in parallel with the normally open limit switch 350. The relay 344 is provided with a second normally open contact which connects a coil 35| of a relay 352 across the busses. The relay 342 also is provided with a second normally open contact which is connected in parallel with the last-mentioned normally open contact of the relay 344. Energization of the coil 35| connects a motor 353, which is arranged to open and close the switch 48, across a suitable three-phase power supply indicated generally at 354.

The switches 49 and 50 are operated by similar electric circuits controlled by the relays 286 and 281. The relay 286 is provided with a normally open contact 355 which is connected in series with the operating coil of a relay 356, a normally closed contact provided on a relay 351 and a normally closed limit switch 360 positioned to be actuated by the switch 49. The relay 356 is energized through a normally open limit switch 362 and a normally closed limit switch 36|. The relay 351 is provided with a normally open contact which is connected in parallel with the normally open limit switch 362. Alternate energization of the relays 356 and 351 connects the operating coil of a relay 358 directly across the busses through normally open contacts provided on the relays. The relay 358 connects a motor 355, which is arranged to open and close the switch 49, across the power supply 354. Energization of the motor 355 positions the switch 49 in alignment with the gravity conveyor section 44 and thereby connects the conveyor 38 to the mixing machine 23.

When the relay 281 (Fig. 9) is energized, a normally open contact 364 provided thereon connects the operating coil of a relay 366 across the busses 335 and 336 in series with a normally closed contact provided on a relay 361 and a is provided with a normally open contact connected in parallel with the normally closed contact of the relay 361 and the limit switch 310. The relay 361 has its operating coil connected across the busses in series with the normally closed limit switch 31| and a normally open limit switch 312. The relay 361 is provided with a normally open contact connected in parallel with the limit switch 312. Alternate energization of the relays 366 and 361 connects the operating coil of a relay 368 across the busses. the relay 368 connects a motor 365 which is arranged to open and close the switch 50 of the conveyor 38, to the potential supply 354. The limit switches 310, 3H and 312 are positioned on the conveyor 38 with respect to the switch section 50 in the same manner that the limit switches 345, 348 and 350 are positioned with respect to the switch 48.

Energization of stee /ere I Qperation- The conveyor shown in Fig. 1- is designed to deliver tubs 30-30 having a selected batch of ingred'ients therein for the mixing machines 2I to 24, inclusive. In the manufacture of electrical conductors, such a conveyor system may be arranged to supply such a group of mixing machines with different types of insulating or jacketing compounds, such as, rubber compounds, Buna S compounds or Neoprene compounds; In such a system the destination of a tub containing ingredients to be mixed in a particular mixing machine must be determined at the time the tub is first placed on the conveyor 28 due to the fact that allthe tubs are delivered to their respective destinations on a single conveyor. The ingredients for the various compounds to be mixed in the mixing machines are stored in large quantities on the floor 25. A suitable supply of each ingredient is positioned along the level conveyor 28; The conveyor system is arranged so that an adequate supply of batch material tubs 30-30 may be stored at each of the mixing machines 2i to 24, inclusive, in order that a reasonable quantity of empty tubs always is available at the beginning of the level conveyor 28.

Let it be assumed that the busses I I and II I are connected to a 50 v. D. C'. voltage supply source, that the busses 335 and 336 are connected to a 110v. A. 0'. supply source that one or more filled tubs 30-30 are positioned on the spur conveyors 40, 4|, 4'4 and 45 and that several empty tubs are positioned on the conveyor 41. Let it be further assumedthat no material tubs 30-30 are positioned on the conveyors 3i and 32. An empty batch material tub 30 is moved from the conve'yor 5! onto the level conveyor 28- and at that time a dispatcher located at the control panel 60 determines from the indicating lamps GI-BI provided on the panel (it, which of themixing machines 2| to 24, inclusive, is to receive the next tub of material.

Assuming that the indicating lamps BI-Bi provided on the control panel indicate that the mixing machine 22 has less material tubs waiting on the spur conveyor 4| than the other spur conveyors, the operator depresses a push button 65. After the operator stationed at the control panel- 60' presses the button 65, he places suitable indicia on the tub 30 to indicate toother operators positioned along the level conveyor 28 the particular ingredients that are to be deposited in the tub.

The dispatcher continues to move empty tubs onto the conveyor 28 and operates the push buttons 54 to 61, inclusive, in accordance with the quantity of tubs stored at each of the mixing machines as indicated by the lamps 6I-6I provided on the panel 50. The filled tubs 30-30 leave the end of the conveyor 28 and pass onto a gravity conveyor 3I which carries the tubs to a short power conveyor 32 positioned at the entrance of the shaft 34.

The tubs 30-30 have their respective ingredients placed therein and move along the level conveyor 28 at a rate greater than the rate at whichthe hoist 35 and the conveyor 38 can deliver the filled tubs to their respective mixing machines 2I to 24, inclusive. As a result, a number of filled tubs 30-30 collect on the conveyor 3I and await their turn to be carried by the hoist 35 to the gravity conveyor 36 which conveys the tubs to the level power conveyor 38 positioned on the floor 26.

I Let it be assumed, that as the next succeeding five empty tubs were placed on the conveyor 28,

the dispatcher operated: the push. buttons 84 to 61, inclusive, in the following order: 6-1, 66; 64', 64 and 51. It. should. be. noted, that while the push buttons 64' to- 61, inclusive, were operated in the above-mentioned sequence, the interval of time between the operation of the push buttons is substantially less than the time required for each tub to pass along the conveyor 28' and be delivered to its respective mixing machine. As" a result, the tubs collect on the conveyor 3I and the control circuit controlling the destination ofeach tub in accordance with the operation of each button must be registered in the coordinate switching apparatus shown in Fig. 3, while the tubs wait to'be carried in turn to the conveyor 38 by the hoist 35. This feature of the invention will be understood more readily if the response of the control apparatus shown in Figs. 6 to 11, inclusive, is noted as each push button is operated.

The push button 65' (Fig. 7), which was the push button operated by the dispatcher when the-first tub was. placed on the conveyor 28 closes its normally open contact and connects the oper-' ating coil Il3 of the relay I2I directly across the busses H8 and III. Operation of the relay l 2'l connects the coil I I- lof the relay I 44 across the busses H0 and HI and the coil I65 of the relay i5! across the busses series with: the open contact of the push button 65 and the normally closed contacts I10 and I'll. Energiz'ation of. the operating coil of the relay I44 closes its normally open contact I'll; which turn connects the operating coil I'Il' of the double-acting magnet (Fig. 7) of the coordinate switch mechanism directly across the busses H0 and III. Energizationof the coil tll rotates the selecting bar 86 and places the resilient fingers attached theretobehind each pair of normally open contacts of the second vertical row of contacts (Fig. 9), of. which the first pair of contacts is indicatedv by the numerals 232 and 233. Energization of the operating coil I'M also closes the contact M3, which in turn, connects the coil l -i'll of the relay HII across the busses H0 and III and thereby closes its contact 2M provided in the control circuit of the holding coil I00.

When the push button 55 is released, the coil I65 of the relay iiil is energized. and closesits normally open contact I58 which connects the operating coil I53 of the relay I54 directly across the busses H0 and III'. The time delay mecha nism: of the relay I2I holds its contacts in their actuated position, and, consequently, holds theoperating coils IM, I'll and M0 acrossthe busses after the push button is released. The energization of the relay I54 closes the normally open contact 240, which in turn, connects the holding magnet coil I00 across the busses H0 and H1 inseries with the closed contact 231 of the relay I 41-, the normally closed push button H and the normally closed contact 242 provided on the relay 2'43. Energization of the coil I 00 also closes its normally open contact 226'. The contact 225' maintains the coil I00 across the busses when the contacts 240 and 24-I drop open upon the expiration of the operating period of the time delay mechanism of the relays I2I and I51. The coil- I00 turns its respective holding bar 99 against the resilient fingers previously positioned adjacent to the first pair of normally open contacts 232 and 233 (Fig.8).

The holding bar 99, actuated by the coil. I00, only closes the contacts 232 and 233 because resilient fingers associated with the contacts 230-231, 234-235, and 236-231 are in their 15 neutral position and pass between the groups of contacts associated with the holding coil I00. Soon after the holding magnet I closes the contacts 232 and 233, the time delay mechanism of the relay I2I releases the contacts to their normal deenergized positions. As a result, the relays HI and I44, and the magnet 80 drop open, whereupon the selecting bar 86 and its associated resilient fingers return to their normal position with the exception of the resilient fingers clamped between the holding bar 99 and the contacts 232 and 233.

It should be noted that when the holding coil I00 was energized and closed its normally open contact 226, the coil of the relay 244 was energized. However, the retarding mechanism of the relay 244 prevents it from closing its normally open contact before the relay I4I drops open and opens the contacts 24I and 248. This arrangement is provided to prevent the holding coil IOI from being energized immediately after the coil I00 is energized, whereby the operation of the button 65 energizes only the holding coil I00. After the relay MI is deenergized by the opening of the relay I2I, the relay 244 closes its contact and thereby sets up a circuit for the relay 241 and the holding coil IOI to be used by the next operation of one of the push buttons.

The operation of the above-mentioned relays takes place immediately upon the actuation of the button 65, and since these relays operate in a very short period of time, the material tub associated with the operation of the push button 65 has not reached the power conveyor 32.

The second tub was placed on the conveyor 28 with the operation of the push button 61, which indicates that the destination of the second tub is the mixing machine 24. Actuation of the push button 61 (Fig. '1) closes its normally open contact and connects the coil 202 of the relay I29 across the busses H0 and III. The closed contact .200 of the relay I29 (Fig. 6) connects the coil I95 of the relay I63 across. the busses H0 and III in series with the normally closed contacts I96, I91 and I93 of the relays I I1, I2I.and I26, respectively, and the open contact of the push button 61. The closed contact 204 energizes the coil 203 of the relay II, which in turn, closes its contact 201 and connects the coil 206 of the bouble-acting magnet 8I across the busses I I6 and II I. The closure of the contact I50 energizes the relay MI toclose the contacts 24I and 248. The contact 248 energizes the relay 241 through the closed contact of the relay 244, whereby the relay 241 closes its contacts 246 and 249. The energization of the coil 206 turns its associated selecting bar 88 so as to position its resilient fingers adjacent t all the normally open contacts of the fourth vertical row of contacts, of which the first pair are numbered 23 6 and 231 (Fig. 9).

When the push button 61 is released, it connects the coil I95 across the busses in series with the contact 200 of the relay I29. The coil closes its contact I62 which energizes the relay I54 and closes all its normally closed contacts, of whichthe contact 245 completes the circuit to the holding coil IOI through the contact 246 of the relay 241 and the normally closed reset button 12. The energization of the coil I0l turns its respective holding bar, which in turn, presses the resilient finger of the selecting bar 88 against the second pair of contacts in the fourth vertical row and closes them. The other resilient fingers attached to the selecting bar 88 (Fig. 9) pass between the contacts comprising the third and fourth vertical rows of contacts of the coordinate mechanism 19. The time delay mechanism of the relay I29 releases its associated contacts immediately after the coil IOI is energized, consequently, the relays I M, I54, and 241 and the double-acting magnet 8I drop open. The closed contact operated by the holding coil IOI maintains the coil across the busses and thereby keeps the second pair of contacts associated with the coil .206 of the coordinate switch mechanism closed. The time delay mechanism of the relay I63 holds the {relay I54 energized after the relay I29 drops open for a period of time sufiicient for the coil IOI to close. The coil of the relay 250 is energized when the coil IOI closes its contact, but the time delay in closing mechanism of the relay 250 prevents it from closing before the relay I 4| drops open and deenergizes the relay 241. This prevents energization of the relay 25I and subsequent energizing of the holding coil I02 at this time. Thus, the operation of the relay I54 energizes only the first open circuited holding coil, namely IOI, when counting down from the coil I00 in Fig. 7, when the push button 61 is actuated.

The operation of the push button 66 when the third tub 30 was placed on the conveyor 28, energizes the coil I81 of the relay I26 and operates its associated normally open and normally closed contacts. Energization of the relay I26 picks up the relays I41, MI, 241 and the relay 25I through the closed contact of the relay 250 in the manner described for the operation of the relays I2I and I29 and energizes the coil I93 of the double-acting magnet 80. Energization of the relay 25I sets up a circuit for the holding coil I 02 through a normally open contact of the relay I54 in the same manner that the contact 245 of the relay sets up the circuit 'for the coil IOI. The operation of the coil I93 positions the resilient fingers of the selecting bar 88 adjacent to the third vertical row of normally open contacts (Fig. 9), of which the first pair are numbered 234 and 235.

When the push button 66 is released, it energizes the relay I6I which in turn energizes the relay I54. Energization of the relay I54 closes its normally open contacts, one of which completes the circuit for the holding coil I02 through the normally closed push button 13. The coil I02 turns its respective holding bar, which in turn, presses the resilient finger adjacent to the third pair of contacts of the third vertical row of contacts and closes them. The coil of the relay 252 is energized when the coil I02 closes its normally open contact and seals itself closed, but the time delay in closing mechanisms of the relay 252 prevents it from closing before the relay I4I drops open. This prevents the energization of the relay .2-53 and subsequent energization of the coil I03 when the push button 66 is actuated. Therefore, the operation of the relay I5 4 energizes only the first open circuited holding coil, namely the coil I02 of the coordinate switch mechanism.

The operation of the push button 64, when the fourth tub 30 was placed on the conveyor 20, connects the operating coil I30 and the relay II1 across the busses H0 and III. Energization of the relay II1 picks up the relays I35 and MI, whereby the relay I35 energizes the. coil I31 of the double-acting magnet (Fig. '1) and the relay I4I energizes the relays 241, 25I and 253 in that order through the contacts of the relays -21 l'4;in and-"252; respectively. These "relays set up a 1 circuit :for the "holding coil ll 03 and: acircuit for theoperatingcoil of the relay wt. The energizationof the coil I37 rotates its selectin 10911 '86so as to position its resilient fingers opposite each pair of normal-lyopen contacts of the first row of contacts, of which-the first pair are numbered 230 and 23!.

Whenthe push button-B4 is released, it-ener- 'gizes the relaysfil l5 and I54. The-relay l54, when energized closes its normally open contacts; one

of which connectsl the holding coil 103 across the busses in series withthe-reset' button T4 and the closed contact of therelay -253. The holding bar actuated by the coil lfl3, engages the resilient finger adjacent to the 'fourth' pair of con'taots of thefirst vertical row of contactsand clos'es the contacts. "closes its normallycopen contact which iscon- The energization'of the coil 403 also nected to maintain theooil 103 acrossithe busses and holds the fourth pair of contacts closed'when the time-delay mechanism of therelay "I ll releases its 'contact and deenergizes the relays 135 Ml 241; -25 I" land 253.

The coil of the .relay 254 is energized'when the coil [03 'closesits' normally=open contact, 'but the time -:delay iin closing mechanism-of the relay 254 prevents .it "from closing before the relay I I! "drops open?'and'deenergizes the relays 435,141 9247,

251 amazes. Thus, the slowclosing relay254 prevents the energization of the relay ZSBand the subsequent"energization of the coil .lEMnpon the energization of the frela'y' l it. Therefore, when the push' button'sfi is actuated only' th'erholding cell 103 is ienergizedr After the relay 253 .is :deenergizedjthe irelay "2-54 closes and is maintained acrossrthe busses H6 and I'll by the normally openicontact orthe coil 1e31- 'Intthis position,

"the relay 54 -sets .upia circuit 'for the relay/2 5B tofbe-us'ed whenlonerof the push fbuttons subsequently'isioperated.

The operation-70f; the pushrioiitontiit; when the of the first vertical row of'contacts (Fig-8). The

relays :M l' and il 54 energizethe ho'lding coil' l 04 because the previous operation of "the holding coils F-IEii to l ttfiinclusive, therelaystZE-dg fiil, 252 and 2 5a; and .relays 231, 25! an'd ZSS f'set upvcir- .cuits for theioperating'coils 04 and 25.8 w'hichare "completed upon theiclosureo'f the relay 154.

Thelop-eration' of''the'pusha'button"6T 'whenithe sixthitub' is placed on the iconveyor .28, f energizes the: :relay i2 llfwhic h' turn, energizes the relays "I 5i ,JI- iI -ZerlJZEt, "2513,2258 and 26! and the coil "2th of :the double actinglim'agnet tl the man'- -ne'r described above for the previous operation of the push'button'tl; When the pushbutton'tl is releasedtthe holding coillita .ot the coordinate.switchmechanismtiszenergized'and clo'sesfthe *sixthipair oftc'ontacts initheifou'rth vertical row of contacts.

The operation'ofrthe pushbuttons'fl *to Elfinclusive', in the order described; takes place within 'aniinterval' of time :which is insufiicient for. the -conveyor systen1=to delivera tub to its preselected destination before 'the :selection of vthe destination of the next succeeding tub is madeby'the dispatcher. 'As a result-the preselected destinations of the tubs are registered in the coordinate switching mechanism fl 9 "in thezorden in which the "1'8 buttons were operated-so that when the hoist 35" d'livers eachtub to the power conveyor 38, the conveyor will-carry the tubs to' their preselected destinations.

It'has been shown that the relays i ll, H 5 and I35. are energized by the-operation of the push button't i; that the relays I21, 1M and I5! are energizedby the operation of the push button t'fiythat'relayslzfi, Island It! are'en'ergized bythe operation of the push button 66, andthat the relays 129; Mil-and I63 'are energized by 'the operation of the push 'butto'n'fil; Each of the relays ill, IZI' 26 and I29 are provided with three normally closed contacts whichare electrically'connected in the circuits for the coils of therelays H5; l5"l,.l6l and l63so that W'hehany related pairs ofthese relays are operated, such as relays ll! and'll5, the'relay Ill opens its'norm'ally closed contacts andrenders the relays I51, i6! and 16-3 inoperative by their respective push buttons.

When the relay261 (Fig. 8) is energized with the last mentioned operation of the push button 61, one of its closed contacts connects-the coil 253 of the relay 243 (Fig. 9) across the busse's.

Energization of'the coil263' opens 'the normally closed contact 242, which inturn deenergizes-the holding-coils me, Ill! and H12. This allows the contacts 'held closed by their respective "holding barsto drop open whereby the holdirigcoils may be used again to set up circuits inthe coordinate switch mechanism "for subsequent'tubs placed on the'conv'eyor 28'. For the representative'circui't shown in Figsuil and 9,'the first three 'tubs placed on the conveyor must be delivered to' their selected destination before the push button 61 operated to select thedestination of thesixth tub placed on theconv'ey'or 28; However, by' 'using one'ormore crossbar switch mechanisms like that shown in Fig. 3, it isp'ossibleto continue 'to dispatch tubs-on thecon-veyor zt even though the first tub has not'beendelivered' to its preselected destination, because each "crossbar -mechanism is mediately afterthe coilwfi is energized'becaii'se the 'conta'ct 2 81 of the relay Ml must openbefore 'the'contact 2:32 of the'relay 243 can reclose. Asa result, this arrangement permits only'the hold- 'ing coilltfi to'be'energi'zed when all thepreceding holding coils areenergized, in the sam'emanner 'that'the time delay in closing relays 2M, 2583, 252, 254 and 2% permit only one of thecoils 100 to let inclusive; to be energized for each operation of thewpush buttons 54 to '61, inclusive.

Having described theoperatio'n of the control circuits'and apparatus response to theoperation of the push buttons in the selected order, itwill now be shown how'the' hoist -35, therelays 285 to 219, inclusive, and 212 to 21?, inclusive (Fig. 10), and the distributing conveyor 38 cooperate to'deliver the tubs to their preselected destinations.

Whenthe tub associated with-the operation of thepush-button 65 reachestheconveyo'r '32, the

hoist 35 is resting'at the bottom of the-shaft and is holding the normally open contactof the limit switch 282 (Fig. 10) closed; In this position the switch 28! connects the operating coil of the relay -2t5acrossthe'busses' llfland -l H :inseries with'the normally "closed contacts of the relays 265 to 210, inclusive, and the normally closed contact 28| of the relay 251. When the hoist is at the bottom of the shaft it also energizes the conveyor 32, whereby the conveyor 32 drives the tub on the hoist 35, which immediately carries it to the floor 26 and delivers it to the gravity conveyor 36. When the hoist leaves the bottom of the shaft, the limit switch 282 closes its normally closed contact and connects the operating coil of the relay 212 across the busses 0 and I in series with the normally closed contacts on the relays 212 to 216, inclusive, the previously closed contact of the relay 265 and the normally closed contact 28| of the relay 251. Thus, this trip of the hoist 35 energizes the relays 265 and 212 which close their respective normally open contacts shown in Fig. 10 and contacts 328 and 292, respectively, shown in Fig. 8, and also maintain themselves across the busses.

As the tub, which was dispatched with the operation of the push button 65, travels along the gravity conveyor 36 it closes the limit switch 3| 2. (Figs. 1 and 9) whereupon the operating coil 290 of the relay 285 is connected across the busses H and III in series with the contacts 292 and 293, the contact 232 associated with the magnet coil I11, the bus 294 and the limit switch 3|2. The energization of the coil 290 closes a normally open contact 340 which connects the operating coil 34l of the relay 342 directly across the busses 335 and 336 in series with the normally closed contact 343 provided on the relay 344, and a normally closed limit switch 345 associated with the operation of the switch section 48. Energization of the relay 342 energizes the coil 35! of a contactor 352, which in turn, connects the motor 353 which drives the switch 46 across the power supply 354. The motor opens the switch section toward the spur conveyor 4|, and when the switch section is aligned with the spur conveyor 4| it opens the limit switch 345 which deenergizes the relay 342 and the relay 352, whereupon the motor is disconnected from the power supply. The tub travels down the power conveyor 36 through the switch section 48 to the spur conveyor 4| which delivers it to a position adjacent to the mixing machine 22.

As the tub passes a predetermined point on the spur conveyor 4|, it closes the limit switch 350.

When the switch section 48 was moved from its straight line position by the motor, it allowed the limit switch 348 to assume itsnormally closed position, in which case, when the tub closes the switch 350, it connects the operating coil 341 of the relay 344 across the busses 335 and 336. Energization of the relay 344 energizes the relay 352 which again connects the motor 353 to the power supply 354. This subsequent energization of the motor 353 is arranged to return the switch section 48 to its straight line position with respect to the power conveyor 38. When the switch section 48 reaches its straight line position, it opens the limit switch 348 and thereby deenergizes the relays 344 and 352 and disconnects the motor 353 from the power supply.

While the tub 30 associated with the operation of the push button 65, is travelling to its destination via the conveyor 38 and the switch section 48, the hoist returns to the floor 20 to pick up the second tub dispatched on the conveyor 28 with the operation of the push button 61, which tub now is resting on the conveyor 32. When the hoist reaches the bottom of the shaft, it actuates the limit switch 282 to connect the operating coil of the relay 266 across the busses 0 and MI in the manner described for the operation of the relay 265. The conveyor 32 drives the tub on the hoist and the hoist carries it to the conveyor 36 on the floor 26. As the hoist leaves the floor 20, the limit switch recloses and connects the operating coil of the relay 213 across the busses in the manner described for the relay 272.

Referring back to the operation of the push button 61 by the dispatcher, it is noted that its operation energized the operating coil 206 of the double-acting magnet 8| and the holding coil |D| of the coordinate switch mechanism. The operation of these coils closed the second pair of normally open contacts of the fourth vertical row of contacts associated with the magnet coil 206. Therefore, when the batch material tub associated with the operation of the push button 61 leaves the hoist 35 and closes the limit switch 3|2 positioned adjacent to the conveyor 36, the switch 3|2 connects the operating coil 309 of the relay 281 across the busses H0 and III in series with the intermediate bus 3, one of the normally open contacts of the second pair of contacts associated with the relay 206, the previously closed contact 295 of the relay 213, and the normally closed contact 296 provided on the relay 261.

The energization of the relay 266 closes its contact 329 which bridges the reset push button 12, whereby the destination of the second tub associated with the operation of the push button 61 can not be changed after the hoist actuates the switch 282 to energize the relay 266. When the operating coil 309 of the relay 281 is connected across the busses, it closes its normally open contact 364 which connects the operating coil of the relay 366 (Fig. 10) directly across the busses 335 and 336 of the motor control circuit. While this material tub is moving toward the power conveyor 38, the operation of the switch 3|2 by the tub energized the relay 366, which in turn, energizes the relay 368 and connects the motor 365 to the power supply 354. The motor 365 turns the switch 50 into alignment with the spur conveyor 45. When the switch 50 is aligned with the spur conveyor 45 it opens the normally closed switch 310 and deenergizes the relays 366 and 368 whereupon the motor 365 is disconnected from the power supply.

The second tub 30 positioned on the conveyor 28 and associated with the operation of the button 61 passes through the switch 50 to the spur conveyor 45 which carries it to the mixing machine 24. As the tub travels along the conveyor 45 it closes the limit switch 312. When the switch 50 was moved from its straight line position with respect-to the conveyor 38, it allowed the switch 31| to assume its normally closed position. Thus, when the tub closes the switch 312, the operating coil of the relay 361 is connected across the busses 335 and 336. This energizes the operating coil of the relay 361 and closes its normally open contacts, one of which energizes the relay 368 which connects the motor 365 to the power supply. The motor 365 moves the switch 50 back into its straight line position with respect to the conveyor 38, and when the switch is aligned with the conveyor 38 it opens the switch 31| which deenergizes the relays 361 and 368. This causes the motor 365 to be disconnected from the power supply and the switch remains in this position until the motor 365 is actuated to direct another tub to the mixing machine 24.

The hoist 35 returns to the floor 20, whereupon the power conveyor 32 delivers the third tub open contacts of the fourth vertical row of contacts. One of these contacts connects the second lamp of the fourth vertical row of lamps in the bank 10 directly across the busses I I and I I l in series with the normally closed contact 32I on the relay 261 (Figs. '7 and 9). The actuation of the push.buttons 66, 64, 64 and 61 in the named order energizes the third lamp in the second vertical row, the fourth and fifth lamps in the first vertical row and the sixth lamp in the third vertical row of lamps in the lamp bank 10 in the same manner as that described for the energization of the lamps in the first and second rows of the lamp bank.

The lamps remain lighted after the push buttons have been actuated until the hoist 35 actuates the limit switch 282 as it returns to the floor 20 after each trip to the floor 26.

For example, when the tub associated with the operation of the push button 65 is picked up by the hoist, the relay 255 is energized and opens its normally closed contact 320 and thereby disconnects the first lamp in the second vertical row of lamps from the busses. This operation is repeated for each operation of the hoist with respect to the lamps which were lighted according to the sequence of operation of the push buttons. Thus, the sequence operation of the push buttons 64 to 61, inclusive, is indicated by the lamps in the lamp bank 10 only so long as the preselected destinations of the tub can be cancelled by the dispatcher at the control panel 50.

It has been shown hereinabove that when the hoist receives a particular tub and leaves the floor 20, the destination of that particular tub can not be cancelled by the operation of the reset push button associated with the preseleceted destination of the tub because the normally open contacts 328 to 333, inclusive, provided on the relays 265 to 210, inclusive, bridge the reset button as the relays are energized by the operation of the switch 282 by the hoist to energize the relays. For example, the normally open contact 328 (Fig. 7) bridges the push button 1|, the normally open contact 328 bridges the push button 12, and the normally open contact 330 bridges the push button 13 and so forth as the relays 265 to 210, inclusive, are energized.

It is believed to be apparent from the description of the operation of the sequence selecting relays 265 to 210, inclusive, and 212 to 211, inclusive, that the destination of the batch material tubs 30-30 may be changed by the dispatcher at the control panel 80 at any time before the hoist returns for the particular tub whose destination is to be changed. After the hoist picks up the particular tub in question, its destination is fixed by the operation of one of the sequence selector relays 212 to 211, inclusive, associated with the operation of the particular trip of the hoist, and, at the same time the lamps associated with the selection of the destination of the particular tub is deenergized showing that it has reached a point in its delivery where its selection can not be altered since the associated control circuit has been set up to carry it to its preselected destination.

It should be noted that the operation of the button 61 when the sixth tub was placed on the conveyor 28, picked up the relays MI, 241, 25I, 253, 258 and 26l (Fig. 7) in the order named so as to set up a circuit for the coil 263 of the relay 243. The subsequent energization of the magnet coil I05, when the button is released, connects the operating coil 263 of the relay 243 directly acrossv the busses I I0 and I I I in series with the normally open contact associated with the coil I05 and the normally open contact of the relay 26L Energization of the coil 263 opens the normally closed contact 242, in which case, the holding coils I00 to I02, inclusive, are disconnected from the busses I I0 and l I whereupon the coils allow their holding bars to return to their normal positions. As a result, the contacts held in their closed position by these coils return to their normally open positions. Consequently, there are only three circuits remaining in the coordinate switching system to be carried out as the first three circuits have been cleared so that the destination of subsequent tubs positioned on the conveyor 28 may be stored by the holding magnets I00 to I02, inclusive.

When the hoist picks up the sixth tub and. carries it to the floor 26, the limit switch 282 recloses and connects the coil of the relay 211 across the busses I I0 and II I in series with contacts on the relays 210 and 251. The energization of the relay 211 connects the operating coil 283 of the relay 251 directly across the busses I I0 and III in series with the closed contact of the relay 211 and the normally open contact of the switch 282. Therefore, when the hoist returns to the floor 20 after delivering the sixth tub to the floor 26 and actuates the switch 282, the operating coil 283 of the relay 251 is energized and opens the normally closed contacts 256 and MI. The opening of the contact 256 disconnects the operating coils I03 to I05, inclusive, from the busses whereupon their holding bars release the contacts associated with the double-acting magnets and 8|. This operation of the relay 251 clears the remaining circuits of the coordinate switch mechanism so that they may be used again to store up circuits as subsequent batch material tubs are placed on the conveyor 28. Thus, each time the relay 243 and 251 are energized, the above-described portions of the coordinate switch mechanism are cleared so the respective holding coils may be used for setting up circuits for the preselected destination of subsequent material tubs as they are positioned on the conveyor 28. By virtue of this arrangement, when the maximum number of circuits have been stored up in the coordinate switching system, the apparatus operates to clear the first portion so that it may be reused while the remaining portion carries out the preselected control circuits for the tubs associated with the operation of that particular portion. Likewise, the opening of the contact 28I deenergizes the coils of the relays 265 to 210, inclusive, and 212 to 211, inclusive, whereupon these relays drop open.

Let it be assumed that the material tubs 3030 have been placed on the conveyor 28 in the order named and discussed hereinabove. As the conveyor system operates to deliver the material tubs to their preselected destination, it may happen that one of the mixing machines 2| to 24, inclusive, has changed the picture originally presented by the indicating lamps 6I-6I on the panel 60 at the time the tub was placed on the conveyor 28. When such a condition arises the dispatcher may wish to cancel a preselected destination of a material tub and reroute it to another mixing machine that appears in immediate need for material of the type in one of the tubs already dispatched to another destination.

Let it be assumed that the preselected destination of the sixth tube to the mixing machine 24 by the second operation of the push button 61 is to be cancelled so that the tub can be rerouted 

